Systems and methods for incorporating a patch antenna in an implantable medical device

ABSTRACT

Systems and methods for an implantable medical device which utilizes a patch antenna for communicating with an external device. The implantable medical device includes a housing, a header, and a patch antenna formed using an RF plate and a ground plate, which may be or include a metal surface of the housing. Also, a material of the header forms a dielectric of the patch antenna.

FIELD OF THE INVENTION

Aspects of the present invention relate to medical apparatus andmethods. More specifically, the present invention relates to systems andmethods for implementing a patch antenna on an implantable medicaldevice.

BACKGROUND OF THE INVENTION

Implantable pulse generators (IPGs) come in a variety of forms fordifferent applications. For example, some IPGs, such as pacemakers andimplantable cardioverter defibrillators (ICDs), are used in thetreatment of cardiac conditions. Other IPGs, such as neuromodulators orneurostimulators, are used in chronic pain management or the actuationand control of other body systems. These devices, which are known asimplantable medical devices (IMDs), commonly include a housing (i.e.,can), feedthrus, and a connector assembly that is enclosed in a header.Electrical stimulation originating in the housing is led to theconnector assembly through the feedthrus. The connector assembly servesto transmit electrical signals out of the implantable medical device andto a lead electrically connected to the connector assembly, the leadtransmitting electrical signals between the implantable medical deviceand patient tissue.

IMDs often communicate with an external unit while the device is stillimplanted. Traditional wireless implantable devices have used inductivetelemetry to communicate. However, an inductive interface requires arelatively short distance (on the order of centimeters) between theimplanted device and the extracorporal unit with which it communicates.This, in turn, may be inconvenient for the patient as well asimpractical for the personnel conducting the procedure. Moreover, themaximum data rate for an inductive interface is relatively low, whichresults in practical limitations as to the amount of data that can becommunicated.

Still other wireless implantable devices use the MICS (Medical ImplantCommunication Service) frequency band of 402-405 MHz. At this frequency,antennas need to be relatively large compared to the size of the headerin order to function well. This has led to the widespread use of wiretype antennas such as the monopole (open loop), closed loop, or invertedF. These antennas have proven to be very versatile with their ability toconform to the shape of the header and route around bore holes and leadconnectors. However, this means that any changes to an existing or newheader on the IMD can lead to significant or complete redesigns of theantenna. Also, header sizes may have to grow in height to accommodatethese antennas.

Therefore, there is a need in the art for a communication system forIMDs which is small enough to fit within a device header.

SUMMARY

The communication arrangements and methods disclosed herein allow for apatch antenna which can be made small enough to fit in a device header,where advantages over monopole and loop antennas can be utilized toimprove RF performance and communication range.

Recently, Bluetooth Low Energy (BLE) communication operating at2.40-2.48 GHz has been found to be a reliable means of RF communicationin implantable medical devices. The introduction of BLE communicationsopens the door for a different type of antenna to be used in implantabledevices, specifically, a patch antenna. Because the size of the patchantenna is inversely proportional to the operating frequency, the higherBLE frequency means the size of the antenna can be decreasedsignificantly to a size that is more reasonable for a device header.Previously, with MICS communication, the only way to accommodate thelarge patch antenna size was to place the antenna on the broad side ofthe housing, such as described in U.S. Patent Application 2003/0216793(incorporated herein by reference in its entirety). However, placing anantenna on the side of the housing is not ideal for a variety ofreasons, such as lack of manufacturing feasibility as well as durabilityof an exposed antenna when implanted.

A basic patch antenna is made up of two rectangular metal plates. Oneplate, normally on the bottom, is the ground and the other top plate isthe signal. In between the two plates is a dielectric material. In someembodiments disclosed herein, the patch antenna employs a single plateand uses a metal surface of the housing (i.e., can) and/or an extensionmember extending therefrom to act as the ground plate. The headermaterial can serve as the dielectric between the two metal surfaces ofthe two plates. Using the housing surface allows the antenna to besmaller, able to be enclosed within the header, and easier tomanufacture than a conventional two-piece patch. Employing the materialof the header as the dielectric for the patch antenna also saves spaceand simplifies manufacturing. Such configurations, at Bluetoothfrequencies, allow the patch antenna to take up a smaller crosssectional area than other antennas, such as the monopole and loopantennas.

In additional to being smaller than other antennas, it is also easier totune the critical parameters of a patch antenna such as frequency,bandwidth, and impedance. Since the RF plate forms a capacitor with thecan surface, the dimensions, shape, and height of the RF plate determinethose critical parameters. In addition, the basic patch antenna can takeon several different implementations in order to decrease size andimprove flexibility if space within the header is tight. Some of theseimplementations will be described in detail and shown in the drawings.

In one embodiment, an implantable medical device has a housing ofelectronics, a header, and a patch antenna. The housing is coupled tothe header and encloses a connector assembly. A polymer material of theheader surrounds or is otherwise associated with the connector assembly.The patch antenna can be formed by electrically connecting a plate tothe electronics contained within the housing. This electrical connectioncan, for example, occur via an RF pin using a feedthru in the metalsurface of the housing. The plate and metal surface together form thepatch antenna, with the metal surface acting as a ground plate of theantenna.

The header can cover, enclose, or otherwise encapsulate the plate,thereby protecting the antenna from outside elements and contamination.In addition, the header material can form the dielectric of the patchantenna, being formed such that the header material is located betweenthe plate and the metal surface.

In one configuration, the patch antenna can be shorted to the metalsurface by connecting a ground pin to an opposite portion of the platefrom where the RF pin connects.

The implantable medical device can, for example, communicate in aBluetooth™ frequency band via the patch antenna. For example, the patchantenna can communicate in frequencies including 2.40 to 2.48 GHz.

The orientation and location of the patch antenna with respect to thehousing can vary among configurations. For example, in oneconfiguration, the patch antenna can have a planar orientation which isparallel to the planar orientation of the portion of the housingassembly which connects to the header connector assembly. In anotherconfiguration, the patch antenna can have a planar orientation which isperpendicular to the planar orientation of the portion of the housingwhich connects to the header connector assembly. In such a verticalorientation, a metal flap or surface can likewise be formed to bevertically parallel to the plate, thereby forming the ground plate ofthe patch antenna. This vertical patch antenna can, for example, beuseful where the header has more space in the vertical direction thanthe horizontal direction.

In yet another configuration, the metal surface forming the ground plateof the patch antenna can be folded around the radiating plate,effectively doubling the size of the original patch antenna.

In another embodiment, an implantable medical device can have a housingassembly which encloses electronics and which has a metal surface with afeedthru opening. The implantable medical device can also have a patchantenna made of a plate electrically connected to the electronics via apin extending through the feedthru opening.

In one configuration of such an embodiment, a header assembly can beattached to the housing assembly, where the header assembly encloses thepatch antenna. The patch antenna can be formed using the plate and themetal surface of the housing assembly, where the metal surface forms aground plate. In some configurations, the header material which formsthe header assembly can be used as a dielectric for the patch antenna,with the dielectric being located between the plate and the metalsurface.

In some configurations, rather than using a metal surface of the housingassembly to form the ground plate of the patch antenna, a feedthruflange can be used as a ground plate. This feedthru flange can be,together with the plate, oriented vertically with respect to the pinwhich is electrically connected to the electronics.

If no flange is used, the plate will likely be in a perpendicularorientation with respect to the pin such that the patch antenna isformed in a parallel planar orientation with respect to the housingassembly.

An exemplary method embodiment for manufacturing the implantable medicaldevices described herein could include: identifying a resonancefrequency for communications between an implantable medical device andan exterior device, the implantable medical device comprising: anhousing having a metal surface and enclosing electronics, the metalsurface having a feedthru opening; a patch antenna comprising a plateelectrically connected to the electronics via a pin extending throughthe feedthru opening, the metal surface of the housing forming a groundplate for the patch antenna; and a header attached to the housing, theheader enclosing the patch antenna; and modifying, based on theresonance frequency, at least one of a plate size of the plate, a shapeof the plate, a distance between the plate and the metal surface, alocation of the feedthru opening, and a length of the pin. The patchantenna can also be shorted to the metal surface by a second pin at anopposite edge of the plate from the pin.

The modifying can alter at least one of a capacitance and an inductanceassociated with the patch antenna. In addition, the header can be formedusing a header material, where the header material serves as thedielectric for the patch antenna. The type of header material usedwould, in such configurations, modify the resonance frequency, andaccordingly the method can further include modifying or otherwiseselecting the header material based on the resonance frequencyidentified.

A second method embodiment directed to manufacturing an implantablemedical device can include forming a patch antenna of the implantablemedical device by delivering a material between an RF plate of the patchantenna and a ground plate of the patch antenna, the material acting asa dielectric of the patch antenna and also forming a header thatencloses a connector assembly of the implantable medical device.

Disclosed herein is an implantable medical device. In one embodiment,the device includes a header connector assembly and a patch antenna. Theheader connector assembly includes a connector assembly and a headerenclosing the connector assembly. The housing is coupled to the headerconnector assembly and includes a metal surface. The housing encloseselectronics for the implantable medical device. The patch antenna isenclosed by the header and includes an RF plate and a ground plate. Amaterial forming the header serves as a dielectric of the patch antenna.

In one embodiment, the RF plate is electrically connected to theelectronics via an RF conductor through a feedthru in the metal surface.The RF conductor may attach to a first rectangular edge of the plate,and a ground conductor may short the patch antenna to the metal surfaceby electrically connecting a second rectangular edge of the plate to themetal surface, the second rectangular edge being opposite to the firstrectangular edge.

In one embodiment, the patch antenna uses the metal surface as theground plate. The patch antenna may communicate in a Bluetooth frequencyband. The Bluetooth frequency band may be contained within 2.40 to 2.48GHz.

In one embodiment, the patch antenna may have a planar orientation whichis parallel to the metal surface. The patch antenna may use the metalsurface as the ground plate.

In one embodiment, the metal surface may include an extension memberextending from the metal surface. The extension member may form theground plate. The metal surface may form a first ground plate and theextension member may form a second ground plate. The extension memberand the planar orientation of the patch antenna may be perpendicular toa planar orientation of the metal surface immediately adjacent the RFplate.

In one embodiment, the extension member may be folded around the plate.The plate may be sandwiched between the extension member and metalsurface.

In one embodiment, the RF plate and the ground plate are spaced apartfrom the adjacent metal surface. The ground plate may wrap around the RFplate such that the RF plate is sandwiched between offset parallel firstand second portions of the ground plate. The RF plate and the groundplate may be parallel with the metal surface immediately adjacent the RFplate. Alternatively, the RF plate and the ground plate are not parallelwith the metal surface immediately adjacent the RF plate.

In one embodiment, the material may include at least one of athermosetting polymer, an epoxy, thermoplastic, polyurethane, tecothane,pellethane, silicone, acrylic, or bionate.

In one embodiment, the dielectric material used by the patch antenna isdistinct from the material used by the header. In such a scenario, thepatch antenna is formed with a first material between the RF plate andthe ground plate, at which point the header is formed around thecompleted patch antenna using a second material.

Also disclosed herein is a method of manufacturing an implantablemedical device. In one embodiment, the method includes forming a patchantenna of the implantable medical device by delivering a materialbetween an RF plate of the patch antenna and a ground plate of the patchantenna, the material acting as a dielectric of the patch antenna andalso forming a header that encloses a connector assembly of theimplantable medical device.

In one embodiment of the method, the material may include at least oneof a thermosetting polymer, an epoxy, thermoplastic, polyurethane,tecothane, pellethane, silicone, acrylic, or bionate. Also, the materialmay be delivered via at least one of injection or casting.

In one embodiment of the method, the ground plate may include a metalsurface of a housing of the implantable medical device, the housingenclosing electronics of the implantable medical device and operablycoupled to the header.

While multiple embodiments are disclosed, still other embodiments of thepresent disclosure will become apparent to those skilled in the art fromthe following detailed description, which shows and describesillustrative embodiments of the disclosure. As will be realized, theinvention is capable of modifications in various aspects, all withoutdeparting from the spirit and scope of the present disclosure.Accordingly, the drawings and detailed description are to be regarded asillustrative in nature and not restrictive.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an isometric view of an exemplary patch antenna.

FIG. 2A is an isometric view of a representative header.

FIG. 2B is an isometric view of a representative connector assembly usedwith the header of FIG. 2A to form a header connector assembly.

FIG. 3A is an isometric view of an IMD.

FIG. 3B is an exploded isometric view of the same IMD, wherein theheader connector assembly is spaced apart from the housing.

FIG. 4A is an isometric view of an IMD having a patch antenna on ahousing with an alternative header design.

FIG. 4B is a close up view of the patch antenna illustrated in FIG. 4A.

FIG. 4C is a rotated view of the patch antenna illustrated in FIG. 4A.

FIG. 5 is an isometric view of an exemplary shorted patch antenna.

FIG. 6 illustrates an isometric view of a patch antenna in a verticalorientation.

FIG. 7 illustrates an isometric view of a folded patch antenna with aground plate folded around the RF plate and a ground plate using themetal surface of the can.

FIG. 8 illustrates an isometric view of a folded patch antenna with aground plate folded around the RF plate where the ground plate is notthe metal surface of the can.

DETAILED DESCRIPTION

Implementations of the present disclosure involve an implantable medicaldevice (IMD) for communication with an external unit using a patchantenna. The IMD generally includes a housing for electronics and aheader, the header allowing the electronics within the housing tointeract with the implanted organism via leads and other mechanisms. Thepatch antennas disclosed herein are sized such that they can fit withinthe header assembly, and can utilize the top surface of the can (thehousing assembly) as a ground plate. Advantages of the disclosedconfigurations and methods include a smaller antenna profile compared toalternative communication mechanisms, where modifications to the headerdesign will have less impact on the antenna design. In addition, theresonant frequency of the patch antenna can be adjusted for specificcircumstances and designs, and provides improved radiation efficiency.

Patch antennas disclosed herein use a sheet of metal, or patch, that isparallel with the can surface. The patch is held a specified distanceaway from the can using the header material in-between to serve as thedielectric medium. The patch plate is welded to a feedthru pin whichconnects the antenna to the RF circuit inside the can. Since the cansurface serves as the antenna ground, it must also be connected to theRF circuit ground on the device. In a most basic implementation, thepatch plate is a single square or rectangular sheet of metal that formsa capacitor with the can ground. For patch antennas, the RF signal isfed at a specific location on the patch and then radiated through thefringing electric fields formed between the edges of the plate and thecan surface below. Due to these fringing fields, the patch plate mustalways be smaller than the size of the can surface.

Patch antenna design allows for the antenna and can to be represented asa capacitor (patch) in series with an inductor (feedthru pin) to createa resonance point. To change the resonance frequency, a few parameterscan be modified such as patch plate size and shape, distance betweenpatch plate and can, location of the feedthru pin connection to thepatch plate, and length of the feedthru pin. Each of these parameterswill alter either the capacitance or inductance of the antenna thereforeshifting the resonance frequency.

Several different implementations can be made to make the basic patchantenna smaller and more flexible. In one embodiment, the RF plate ofthe patch antenna can be shorted to ground in order to change thecurrent distribution around the patch plate and effectively decrease itssize. The shorting pin also adds an extra inductive element to aid intuning the antenna to the correct resonance frequency.

FIG. 1 illustrates an isometric view of an exemplary patch antenna 100.A patch antenna 100 is made up of two rectangular metal plates 102, 106.One plate 106, illustrated on the bottom, is the ground and the othertop plate 102 is the signal or RF plate. In between the two plates is adielectric material 104. At Bluetooth™ frequencies, the patch antennacan be designed to take up a smaller cross sectional area than otherantennas such as the monopole and loop antennas. The signal is fed tothe top plate 102 via an RF conductor (e.g., RF pin) 108, and the groundplate 106 is grounded using a grounding conductor (e.g., pin) 110.

In addition to being smaller than other antennas, it is also easier totune the critical parameters of a patch antenna such as frequency,bandwidth, and impedance. Because the patch forms a capacitor with thecan surface, the dimensions, shape, and height of the patch platedetermine those critical parameters. In addition, a patch antenna 100can take on several different implementations in order to decrease sizeand improve flexibility if space within the header is tight. Some ofthese implementations will be described in detail below.

FIG. 2A is an isometric view of a representative header 40 and FIG. 2Bis an isometric view of a representative connector assembly 42. Theheader 40 of FIG. 2A has two receptacles 30 and 33. However, in otherembodiments, the header 40 of FIG. 2A may have two or more receptacles.These receptacles 30 and 33 can be used to for leads and othermechanisms for an IMD to interact with an organism in which the IMD isimplanted.

As illustrated in FIG. 2B, the connector assembly 42 includes tip blocks44 and ring blocks 46. The ring blocks 46 include spring contacts 48.Each electrical block 44 and 46 of the connector assembly 42 serves asan electrical contact of the connector assembly 42. Thus, each tip block44 is configured to receive and make electrical contact with the tipterminal of a lead connector end received in the correspondingreceptacle 30, 33 of the header 40. Similarly, each ring block 46 isconfigured to receive and make electrical contact with the ring terminalof a lead connector end received in the corresponding receptacle 30, 33of the header 40. While the connector assembly 42 of FIG. 2B is of anIS-1 configuration, other configurations (e.g., IS-4, etc.) can be usedin other embodiments. While the connector assembly 42 of FIG. 2B onlydepicts two pairs of blocks 44, 46, in other embodiments where theheader includes more than a single pair of receptacles 30, 33 (e.g.,more than a single pairs of receptacles 30, 33), such that the connectorassembly 42 will have a multiple pairs of blocks 44, 46.

As shown in FIG. 2B, the connector assembly 42 also includes an A-tiptab 54, an A-ring tab 56, an RV-ring tab 58, an RV-tip tab 60, and otherconductors that extend between the various tabs and their respectiveelectrical contacts of the connector assembly or other componentsthereof. The various tabs are welded to corresponding terminalsextending from circuitry of the IMD. The connector assembly 42 ismanufactured of materials and via methods known in the industry. Theconnector assembly 42 is molded into the header 40 to form the headerconnector assembly, which sits on top of and is coupled to the housing.

FIG. 3A is an isometric view of an IMD 11, and FIG. 3B illustrates thesame IMD 11, but with the header connector assembly 22 spaced apart fromthe housing 24.

As depicted in FIG. 3B, a feedthru 68 and an RF pin 70 with theirassociated terminals extend outwardly from a top surface 26 of thehousing 24 from their respective connections to the electronic circuitrycontained within the confines of the housing 24. The RF pin 70 issurrounded by a round metal surface 72, which is the feedthru flange andwhich is connected to the can/ground. There can also be a piece ofceramic between the RF pin 70 and the feedthru flange 72, which provideselectrical isolation between the RF pin 70 and the feedthru flange 72.In other configurations, the feedthru flange 72 can have alternativeshapes, preferably a rectangle with a size larger than the RF plate usedas a patch antenna. The wires of the feedthru 68 are welded to theirrespective tabs 54, 56, 58, and 60, discussed above with respect to FIG.2B, as well as the patch antenna RF plate to be further discussed.

FIG. 4A is an isometric view of an IMD 400 having a patch antenna 408 ona housing 406 with a connector assembly 407 from that illustrated inFIGS. 2A-3B. In addition, the header 402 is illustrated with dashedlines, with leads 404 extending from the IMD. In this configuration, theIMD 400 has a feedthru flange 410 on the metal surface of the housing406 beneath the connector assembly 407. The feedthru flange 410 can havemultiple layers and can be electrically connected to the metal surfaceof the can. A plate 408 of a patch antenna is likewise illustrated andis sized such that the plate 408 is contained within the header 402.When the plate 408 receives an RF signal from electronics within thehousing 406, the plate, the polymer material forming the header 402, andthe metal surface of the can (including anything grounded to the can,such as the feedthru flange 410) together form a patch antenna, allowingthe signal to be communicated to an external device.

FIG. 4B is a close up view of the patch antenna illustrated in FIG. 4A.With the close up view, the RF pin 414 and feedthru 412 which connectthe plate (also known as the RF plate) 408 are visible. The RF pin 414electrically connects the plate 408 to the electronics internal to thehousing 406. The feedthru plate 412 electrically isolates the RF pin 414from the exterior of the housing, including the metal surface of thehousing (and the feedthru flange 410). As stated before, a patch antennais formed between the plate 408 and the metal surface, with the metalsurface acting as a grounding plate when the plate 408 receives a signalfrom the electronics of the housing 406. The polymer material (notshown) forming the header 402 acts as the dielectric between the twoelectrically conductive surfaces of the patch antenna. The polymermaterial can be in the form of a thermoset polymer (e.g., epoxy) or aninjectable polymer such as, for example, polyurethane, tecothane,pellethane, bionate, silicone, acrylic, or etc. The header material thatencloses the connector assembly forms the header and acts as thedielectric for the patch antenna can be any type of thermoplastic, orany other variety of material that can be caused to flow about andbetween the various elements of the antenna and connector assembly toform the header that encases these electrically conductive components.

FIG. 4C is a rotated view of the patch antenna illustrated in FIG. 4A,similarly showing the plate 408, the feedthru 412, the feedthru flange410 on the metal surface of the housing 406, and the housing 406 itself.In this illustration, the plate 408 is illustrated as centered over thehousing 406, however in other configurations the plate 408 can be movedor located as required for specific functionality. For example, theplate 408 could be moved closer to the left edge of the housing 406, orcould be closer to the top or bottom edge of the illustrated housing406, such that the plate and the resulting patch antenna are notcentered on the IMD.

FIG. 5 is an isometric view 500 of an exemplary shorted patch antenna.In this example configuration, the patch antenna can be shorted toground in order to change the current distribution around the patchplate 408 and effectively decrease its size. The shorting pin 502 canalso add an extra inductive element to aid in tuning the antenna to thecorrect resonance frequency. As illustrated, the shorting pin 502 is onthe opposite end of the rectangular patch panel 408 from the RF pin 414.Moreover, the shorting pin 502 is electrically connected to the metalsurface of the can 406, either directly or (as illustrated) by shortingto the feedthru flange 410.

The patch antenna is not required to be parallel to the surface of thecan. FIG. 6 illustrates an isometric view 600 of a patch antenna in avertical orientation, where the plate 408 is oriented verticallyparallel to a ground plate 602 (flange) which is also orientedvertically. The ground plate 602 is electrically connected to the metalsurface of the can (either directly or, as illustrated, by connectionwith the feedthru flange 410) and continues to act as the groundingplate for the patch antenna. The vertical ground plate 602 may be anextension member 602 of the metal surface and may take the form of aflange, tab, or other structure projecting from the metal surface.

FIG. 7 illustrates an isometric view 700 of a folded patch antenna witha ground plate 702 folded around the RF plate 408 and sandwiching the RFplate 408 between the folded ground plate 702 and a second ground platein the form of the metal surface of the can (and/or the feedthru flange410). The folded ground plate 702 may be an extension member 702 of themetal surface and may take the form of a flange, tab, or other structureprojecting from the metal surface. Because the RF plate 408 will, inthis configuration, have two separate but electrically connected groundplates (the folded flange 702 and the metal surface of the can), theeffective size of the patch antenna is doubled. This allows the patchantenna to decrease in size along the width and length, and instead growtaller. Such a configuration can, for example, be useful inconfigurations where the width and/or length of the patch antenna islimited, but the header is high enough to accommodate a taller antennastructure.

FIG. 8 is an isometric view of a second example of a folded patchantenna. As illustrated in FIG. 8, a folded patch antenna 800 has aground plate 804 folded around the RF plate 802, and the RF plate 802and the ground plate 804 are separate by a dielectric 806. Thisdielectric material 806 could be separately applied from the dielectricmaterial of the housing or could be the dielectric material of thehousing. As illustrated, the patch antenna 800 is physically separatedfrom the can and instead is grounded using a grounding pin 810 betweenthe ground plate 804 and a grounding source on the IMD. Like otherconfigurations previously discussed, the RF plate 802 receives thesignals from electronics via an RF pin 808.

It should be noted, that while the dielectric material between thesurfaces of the plates of the patch antennas discussed herein withrespect to FIGS. 4A-7 is not shown in FIGS. 4A-7, these embodiments willhave a dielectric material that occupies all of the space between thesurfaces of the plates similar to the dielectric material 104, 806depicted in FIGS. 1 and 8, whether the plate be an RF plate or a groundplate. Moreover, such dielectric material for the embodiments of FIGS.4A-8 may be provided via the polymer material that forms the housingthat encloses the connector assembly, as can be understood from FIGS.2A-3B. Such dielectric material may completely enclose and encapsulateeach plate, effectively isolating each plate surface from the surfacesof the other plates except for intentional electrical pathways providedby conductor pins, circuits or an extension of an extension member fromthe metal surface of the housing. Thus, in one embodiment, an IMD asdescribed herein may be manufactured by: electrically connecting theconnector assembly to the corresponding circuits of the electronics inthe housing; assembling the plates of the patch antenna onto the housingsuch that the patch antenna plates are electrically connected to thecorresponding circuits of the electronics in the housing; and formingthe housing about the connector assembly and the antenna plates suchthat the polymer material of the housing forms the dielectric of thepatch antenna, the forming being provided by injection, casting or othermethods.

It is also noted that in certain embodiments, the dielectric materialused by the patch antenna can be distinct from the material used to formthe header. In such embodiments, the patch antenna is formed with afirst material between the RF plate and the ground plate, then theheader is formed around the completed patch antenna using a secondmaterial.

In one embodiment, the implantable medical device may be designed andmanufactured as follows. A manufacturer would identify a resonancefrequency for communications between an implantable medical device andan exterior device. Such an implantable medical device may include ahousing assembly having a metal surface and enclosing electronics. Themetal surface may have a feedthru opening, and may be electricallyconnected to a feedthru flange containing the feedthru opening. A patchantenna of the implantable medical device may include a plateelectrically connected to the electronics via a pin extending throughthe feedthru opening. The metal surface of the housing (and anyelectrically connected feedthru flange) may form a ground plate for thepatch antenna, with the result being that the entire surface of thehousing can be considered the ground plate. A header assembly may beattached to the housing assembly and enclose the patch antenna. Apolymer material may form the dielectric between the surfaces of thepatch antenna. The polymer material in some embodiments is the polymermaterial that forms the header and encloses the connector assembly. Withsuch an implantable medical device, the manufacturer would then modify,based on the resonance frequency, at least one of a plate size of theplate, a shape of the plate, a distance between the plate and the metalsurface, a location of the feedthru opening, or a length of the pin. Themodifying may alter at least one of a capacitance or an inductanceassociated with the patch antenna. The header material may be modifiedbased on the resonance frequency. The plate of the patch antenna may beshorted to the metal surface by a second pin at another location of theplate away from the pin (such as an opposite edge of the RF plate).

The patch antenna can, in various configurations, communicate in aBluetooth™ frequency band, including 2.40 to 2.48 GHz. The patch antennacan have a planar orientation which is parallel to the metal surface ofthe housing assembly or can be perpendicular (i.e., vertical) to themetal surface of the housing and rely on a flange or other piece of bentmetal to form the ground plate of the antenna. The patch antenna canhave a single ground plate or multiple ground plates, and in someconfigurations the multiple ground plates can be formed using a singlegrounded piece of metal which is folded around an RF plate. Similarly,the patch antenna can be shorted, such that the grounding pin is onanother location or portion of the RF plate away from the RF pinproviding a signal to the RF plate.

Once the antenna has the desired resonance frequency, the header can beapplied such that the patch antenna is covered by the header. The headermaterial of which the header is made can act as a dielectric for thepatch antenna. Because the dielectric affects the antenna performance,the choice of header material used for the header can be made based onthe resonance frequency.

The foregoing merely illustrates the principles of the invention.Various modifications and alterations to the described embodiments willbe apparent to those skilled in the art in view of the teachings herein.It will thus be appreciated that those skilled in the art will be ableto devise numerous systems, arrangements and methods which, although notexplicitly shown or described herein, embody the principles of theinvention and are thus within the spirit and scope of the presentinvention. From the above description and drawings, it will beunderstood by those of ordinary skill in the art that the particularembodiments shown and described are for purposes of illustrations onlyand are not intended to limit the scope of the present invention.References to details of particular embodiments are not intended tolimit the scope of the invention.

What is claimed is:
 1. An implantable medical device comprising: aheader connector assembly comprising a connector assembly and a headerenclosing the connector assembly, the header including a dielectricmaterial; a housing coupled to the header connector assembly andcomprising a metal surface, the housing enclosing electronics for theimplantable medical device; and a modular feedthru assembly comprising:a feedthru flange coupled to the housing and electrically connected tothe metal surface; a radio frequency (RF) plate; an RF conductor coupledto the RF plate and electrically connecting the RF plate to theelectronics through a feedthru extending through the feedthru flange,the RF conductor being electrically isolated from the feedthru flangeand the metal surface; and a ground conductor extending between the RFplate and the feedthru flange, the ground conductor directly couplingthe RF plate to the feedthru flange and shorting the RF plate to thefeedthru flange, wherein the RF plate, the feedthru flange, and aportion of the dielectric material extending between the RF plate andthe feedthru flange form a patch antenna, the feedthru flange forming aground plate of the patch antenna extending parallel to at least aportion of the RF plate.
 2. The implantable medical device of claim 1,wherein the RF conductor attaches to a first rectangular edge of the RFplate, and wherein the ground conductor attaches to a second rectangularedge of the RF plate, the second rectangular edge being opposite to thefirst rectangular edge.
 3. The implantable medical device of claim 1,wherein the patch antenna communicates in a Bluetooth frequency bandcontained within 2.40 to 2.48 GHz.
 4. The implantable medical device ofclaim 1, wherein the patch antenna has a planar orientation which isparallel to the metal surface and the ground plate further includes themetal surface.
 5. The implantable medical device of claim 1, wherein thefeedthru flange forms a first ground plate and the implantable medicaldevice further comprises an extension member extending from the metalsurface, the extension member further forming a second ground plate. 6.The implantable medical device of claim 5, wherein the extension memberand the planar orientation of the patch antenna are perpendicular to aplanar orientation of the metal surface immediately adjacent the RFplate.
 7. The implantable medical device of claim 6, wherein theextension member is folded around the plate, and the plate is sandwichedbetween the extension member and metal surface.
 8. The implantablemedical device of claim 1, wherein the dielectric material includes atleast one of a thermosetting polymer, an epoxy, thermoplastic,polyurethane, tecothane, pellethane, silicone, acrylic or bionate.